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Bayesian-optimized riblet surface design for turbulent drag reduction via design-by- morphing with large eddy simulation

Bayesian-optimized riblet surface design for turbulent drag reduction via design-by- morphing with large eddy simulation
Bayesian-optimized riblet surface design for turbulent drag reduction via design-by- morphing with large eddy simulation

A computational approach is presented for optimizing new riblet surface designs in turbulent channel flow for drag reduction, utilizing design-by-morphing (DbM), large Eddy simulation (LES), and Bayesian optimization (BO). The design space is generated using DbM to include a variety of novel riblet surface designs, which are then evaluated using LES to determine their drag-reducing capabilities. The riblet surface geometry and configuration are optimized for maximum drag reduction using the mixed-variable Bayesian optimization (MixMOBO) algorithm. A total of 125 optimization epochs are carried out, resulting in the identification of three optimal riblet surface designs that are comparable to or better than the reference drag reduction rate of 8%. The Bayesian-optimized designs commonly suggest riblet sizes of around 15 wall units, relatively large spacing compared to conventional designs, and spiky tips with notches for the riblets. Our overall optimization process is conducted within a reasonable physical time frame with up to 12-core parallel computing and can be practical for fluid engineering optimization problems that require high-fidelity computational design before materialization.

Bayesian optimization, design for manufacturing, design optimization, design-by-morphing (DbM), drag reduction, large Eddy simulation, multidisciplinary design and optimization, Riblet surface, turbulent channel flow
1050-0472
Lee, Sangjoon
54d46b57-5723-4902-ad3c-71ed56faa45e
Sheikh, Haris Moazam
631e12be-9394-41fd-8e90-6ab416df0d76
Lim, Dahyun D.
ab1d03ca-a629-4bfa-88a7-cab28c6c70be
Gu, Grace X.
ab7eb6ea-d6f6-49ca-921d-09cfae8f2613
Marcus, Philip S.
71925db3-fc73-4df3-93ea-fecc0bd6412b
Lee, Sangjoon
54d46b57-5723-4902-ad3c-71ed56faa45e
Sheikh, Haris Moazam
631e12be-9394-41fd-8e90-6ab416df0d76
Lim, Dahyun D.
ab1d03ca-a629-4bfa-88a7-cab28c6c70be
Gu, Grace X.
ab7eb6ea-d6f6-49ca-921d-09cfae8f2613
Marcus, Philip S.
71925db3-fc73-4df3-93ea-fecc0bd6412b

Lee, Sangjoon, Sheikh, Haris Moazam, Lim, Dahyun D., Gu, Grace X. and Marcus, Philip S. (2024) Bayesian-optimized riblet surface design for turbulent drag reduction via design-by- morphing with large eddy simulation. Journal of Mechanical Design, 146 (8), [081701]. (doi:10.1115/1.4064413).

Record type: Article

Abstract

A computational approach is presented for optimizing new riblet surface designs in turbulent channel flow for drag reduction, utilizing design-by-morphing (DbM), large Eddy simulation (LES), and Bayesian optimization (BO). The design space is generated using DbM to include a variety of novel riblet surface designs, which are then evaluated using LES to determine their drag-reducing capabilities. The riblet surface geometry and configuration are optimized for maximum drag reduction using the mixed-variable Bayesian optimization (MixMOBO) algorithm. A total of 125 optimization epochs are carried out, resulting in the identification of three optimal riblet surface designs that are comparable to or better than the reference drag reduction rate of 8%. The Bayesian-optimized designs commonly suggest riblet sizes of around 15 wall units, relatively large spacing compared to conventional designs, and spiky tips with notches for the riblets. Our overall optimization process is conducted within a reasonable physical time frame with up to 12-core parallel computing and can be practical for fluid engineering optimization problems that require high-fidelity computational design before materialization.

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More information

Accepted/In Press date: 14 December 2023
e-pub ahead of print date: 1 February 2024
Published date: 1 August 2024
Keywords: Bayesian optimization, design for manufacturing, design optimization, design-by-morphing (DbM), drag reduction, large Eddy simulation, multidisciplinary design and optimization, Riblet surface, turbulent channel flow

Identifiers

Local EPrints ID: 493436
URI: http://eprints.soton.ac.uk/id/eprint/493436
DOI: doi:10.1115/1.4064413
ISSN: 1050-0472
PURE UUID: 5c552838-07a8-4a33-8c35-6e0a1c2a984a
ORCID for Haris Moazam Sheikh: ORCID iD orcid.org/0000-0002-3154-0494

Catalogue record

Date deposited: 03 Sep 2024 16:34
Last modified: 04 Sep 2024 02:10

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Contributors

Author: Sangjoon Lee
Author: Haris Moazam Sheikh ORCID iD
Author: Dahyun D. Lim
Author: Grace X. Gu
Author: Philip S. Marcus

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